Normal Distribution - Mathlzhang/teaching/3070spring2009/Daily Updates... · Normal Distribution...

Normal Distribution

Proposition

If X has a normal distribution with mean µ and stadard deviationσ, then

Z =X − µσ

has a standard normal distribution. Thus

P(a ≤ X ≤ b) = P(a− µσ≤ Z ≤ b − µ

= Φ(b − µσ

)− Φ(a− µσ

P(X ≤ a) = Φ(a− µσ

) P(X ≥ b) = 1− Φ(b − µσ

Normal Distribution

Proposition

If X has a normal distribution with mean µ and stadard deviationσ, then

Z =X − µσ

has a standard normal distribution. Thus

P(a ≤ X ≤ b) = P(a− µσ≤ Z ≤ b − µ

= Φ(b − µσ

)− Φ(a− µσ

P(X ≤ a) = Φ(a− µσ

) P(X ≥ b) = 1− Φ(b − µσ

Normal Distribution

Example (Problem 38):There are two machines available for cutting corks intended for usein wine bottles. The first produces corks with diameters that arenormally distributed with mean 3cm and standard deviation 0.1cm.The second produces corks with diameters that have a normaldistribution with mean 3.04cm and standard deviation 0.02cm.Acceptable corks have diameters between 2.9cm and 3.1cm.Which machine is more likely to produce an acceptable cork?

P(2.9 ≤ X1 ≤ 3.1) = P(2.9− 3

0.1≤ Z ≤ 3.1− 3

= P(−1 ≤ Z ≤ 1) = 0.8413− 0.1587 = 0.6826

P(2.9 ≤ X2 ≤ 3.1) = P(2.9− 3.04

0.02≤ Z ≤ 3.1− 3.04

= P(−7 ≤ Z ≤ 3) = 0.9987− 0 = 0.9987

Normal DistributionExample (Problem 38):There are two machines available for cutting corks intended for usein wine bottles. The first produces corks with diameters that arenormally distributed with mean 3cm and standard deviation 0.1cm.The second produces corks with diameters that have a normaldistribution with mean 3.04cm and standard deviation 0.02cm.Acceptable corks have diameters between 2.9cm and 3.1cm.Which machine is more likely to produce an acceptable cork?

P(2.9 ≤ X1 ≤ 3.1) = P(2.9− 3

0.1≤ Z ≤ 3.1− 3

= P(−1 ≤ Z ≤ 1) = 0.8413− 0.1587 = 0.6826

P(2.9 ≤ X2 ≤ 3.1) = P(2.9− 3.04

0.02≤ Z ≤ 3.1− 3.04

= P(−7 ≤ Z ≤ 3) = 0.9987− 0 = 0.9987

Normal DistributionExample (Problem 38):There are two machines available for cutting corks intended for usein wine bottles. The first produces corks with diameters that arenormally distributed with mean 3cm and standard deviation 0.1cm.The second produces corks with diameters that have a normaldistribution with mean 3.04cm and standard deviation 0.02cm.Acceptable corks have diameters between 2.9cm and 3.1cm.Which machine is more likely to produce an acceptable cork?

P(2.9 ≤ X1 ≤ 3.1) = P(2.9− 3

0.1≤ Z ≤ 3.1− 3

= P(−1 ≤ Z ≤ 1) = 0.8413− 0.1587 = 0.6826

P(2.9 ≤ X2 ≤ 3.1) = P(2.9− 3.04

0.02≤ Z ≤ 3.1− 3.04

= P(−7 ≤ Z ≤ 3) = 0.9987− 0 = 0.9987

Normal Distribution

Example (Problem 44):If bolt thread length is normally distributed, what is the probabilitythat the thread length of a randomly selected bolt is (a)within 1.5SDs of its mean value? (b)between 1 and 2 SDs from its meanvalue?

P(µ− 1.5σ ≤ X1 ≤ µ+ 1.5σ) = P(µ− 1.5σ − µ

σ≤ Z ≤ µ+ 1.5σ − µ

= P(−1.5 ≤ Z ≤ 1.5)

= 0.9332− 0.0668 = 0.8664

2 · P(µ+ σ ≤ X1 ≤ µ+ 2σ) = 2P(µ+ σ − µ

σ≤ Z ≤ µ+ 2σ − µ

= 2P(1 ≤ Z ≤ 2)

= 2(0.9772− 0.8413) = 0.0.2718

Normal DistributionExample (Problem 44):If bolt thread length is normally distributed, what is the probabilitythat the thread length of a randomly selected bolt is (a)within 1.5SDs of its mean value? (b)between 1 and 2 SDs from its meanvalue?

P(µ− 1.5σ ≤ X1 ≤ µ+ 1.5σ) = P(µ− 1.5σ − µ

σ≤ Z ≤ µ+ 1.5σ − µ

= P(−1.5 ≤ Z ≤ 1.5)

= 0.9332− 0.0668 = 0.8664

2 · P(µ+ σ ≤ X1 ≤ µ+ 2σ) = 2P(µ+ σ − µ

σ≤ Z ≤ µ+ 2σ − µ

= 2P(1 ≤ Z ≤ 2)

= 2(0.9772− 0.8413) = 0.0.2718

P(µ− 1.5σ ≤ X1 ≤ µ+ 1.5σ) = P(µ− 1.5σ − µ

σ≤ Z ≤ µ+ 1.5σ − µ

= P(−1.5 ≤ Z ≤ 1.5)

= 0.9332− 0.0668 = 0.8664

2 · P(µ+ σ ≤ X1 ≤ µ+ 2σ) = 2P(µ+ σ − µ

σ≤ Z ≤ µ+ 2σ − µ

= 2P(1 ≤ Z ≤ 2)

= 2(0.9772− 0.8413) = 0.0.2718

P(µ− 1.5σ ≤ X1 ≤ µ+ 1.5σ) = P(µ− 1.5σ − µ

σ≤ Z ≤ µ+ 1.5σ − µ

= P(−1.5 ≤ Z ≤ 1.5)

= 0.9332− 0.0668 = 0.8664

2 · P(µ+ σ ≤ X1 ≤ µ+ 2σ) = 2P(µ+ σ − µ

σ≤ Z ≤ µ+ 2σ − µ

= 2P(1 ≤ Z ≤ 2)

= 2(0.9772− 0.8413) = 0.0.2718

Normal Distribution

Proposition

{(100p)th percentile for N(µ, σ2)} =µ + {(100p)th percentile for N(0, 1)} · σ

Example (Problem 39)The width of a line etched on an integrated circuit chip is normallydistributed with mean 3.000 µm and standard deviation 0.140.What width value separates the widest 10% of all such lines fromthe other 90%?

ηN(3,0.1402)(90) = 3.0+0.140·ηN(0,1)(90) = 3.0+0.140·1.28 = 3.1792

Normal Distribution

Proposition

ηN(3,0.1402)(90) = 3.0+0.140·ηN(0,1)(90) = 3.0+0.140·1.28 = 3.1792

Normal Distribution

Proposition

ηN(3,0.1402)(90) = 3.0+0.140·ηN(0,1)(90) = 3.0+0.140·1.28 = 3.1792

Normal Distribution

Proposition

ηN(3,0.1402)(90) = 3.0+0.140·ηN(0,1)(90) = 3.0+0.140·1.28 = 3.1792

Normal Distribution

Proposition

Let X be a binomial rv based on n trials with success probability p.Then if the binomial probability histogram is not too skewed, X hasapproximately a normal distribution with µ = np and σ =

√npq,

where q = 1− p. In particular, for x = a posible value of X ,

P(X ≤ x) = B(x ; n, p) ≈(

area under the normal curve

to the left of x+0.5

)= Φ(

x+0.5− np√

In practice, the approximation is adequate provided that bothnp ≥ 10 and nq ≥ 10, since there is then enough symmetry in theunderlying binomial distribution.

Normal Distribution

Proposition

Let X be a binomial rv based on n trials with success probability p.Then if the binomial probability histogram is not too skewed, X hasapproximately a normal distribution with µ = np and σ =

√npq,

where q = 1− p. In particular, for x = a posible value of X ,

P(X ≤ x) = B(x ; n, p) ≈(

)= Φ(

x+0.5− np√

In practice, the approximation is adequate provided that bothnp ≥ 10 and nq ≥ 10, since there is then enough symmetry in theunderlying binomial distribution.

Normal Distribution

A graphical explanation for

P(X ≤ x) = B(x ; n, p) ≈(

)= Φ(

x+0.5− np√

Normal Distribution

P(X ≤ x) = B(x ; n, p) ≈(

)= Φ(

x+0.5− np√

Normal Distribution

P(X ≤ x) = B(x ; n, p) ≈(

)= Φ(

x+0.5− np√

Normal Distribution

Example (Problem 54)Suppose that 10% of all steel shafts produced by a certain processare nonconforming but can be reworked (rather than having to bescrapped). Consider a random sample of 200 shafts, and let Xdenote the number among these that are nonconforming and canbe reworked. What is the (approximate) probability that X isbetween 15 and 25 (inclusive)?In this problem n = 200, p = 0.1 and q = 1− p = 0.9. Thusnp = 20 > 10 and nq = 180 > 10

P(15 ≤ X ≤ 25) = Bin(25; 200, 0.1)− Bin(14; 200, 0.1)

≈ Φ(25 + 0.5− 20√

200 · 0.1 · 0.9)− Φ(

15 + 0.5− 20√200 · 0.1 · 0.9

= Φ(0.3056)− Φ(−0.2500)

= 0.6217− 0.4013

= 0.2204

Normal DistributionExample (Problem 54)Suppose that 10% of all steel shafts produced by a certain processare nonconforming but can be reworked (rather than having to bescrapped). Consider a random sample of 200 shafts, and let Xdenote the number among these that are nonconforming and canbe reworked. What is the (approximate) probability that X isbetween 15 and 25 (inclusive)?

In this problem n = 200, p = 0.1 and q = 1− p = 0.9. Thusnp = 20 > 10 and nq = 180 > 10

P(15 ≤ X ≤ 25) = Bin(25; 200, 0.1)− Bin(14; 200, 0.1)

≈ Φ(25 + 0.5− 20√

200 · 0.1 · 0.9)− Φ(

15 + 0.5− 20√200 · 0.1 · 0.9

= Φ(0.3056)− Φ(−0.2500)

= 0.6217− 0.4013

= 0.2204

Normal DistributionExample (Problem 54)Suppose that 10% of all steel shafts produced by a certain processare nonconforming but can be reworked (rather than having to bescrapped). Consider a random sample of 200 shafts, and let Xdenote the number among these that are nonconforming and canbe reworked. What is the (approximate) probability that X isbetween 15 and 25 (inclusive)?In this problem n = 200, p = 0.1 and q = 1− p = 0.9. Thusnp = 20 > 10 and nq = 180 > 10

P(15 ≤ X ≤ 25) = Bin(25; 200, 0.1)− Bin(14; 200, 0.1)

≈ Φ(25 + 0.5− 20√

200 · 0.1 · 0.9)− Φ(

15 + 0.5− 20√200 · 0.1 · 0.9

= Φ(0.3056)− Φ(−0.2500)

= 0.6217− 0.4013

= 0.2204

Normal DistributionExample (Problem 54)Suppose that 10% of all steel shafts produced by a certain processare nonconforming but can be reworked (rather than having to bescrapped). Consider a random sample of 200 shafts, and let Xdenote the number among these that are nonconforming and canbe reworked. What is the (approximate) probability that X isbetween 15 and 25 (inclusive)?In this problem n = 200, p = 0.1 and q = 1− p = 0.9. Thusnp = 20 > 10 and nq = 180 > 10

P(15 ≤ X ≤ 25) = Bin(25; 200, 0.1)− Bin(14; 200, 0.1)

≈ Φ(25 + 0.5− 20√

200 · 0.1 · 0.9)− Φ(

15 + 0.5− 20√200 · 0.1 · 0.9

= Φ(0.3056)− Φ(−0.2500)

= 0.6217− 0.4013

= 0.2204

Exponential Distribution

DefinitionX is said to have an exponential distribution with parameterλ(λ > 0) if the pdf of X is

f (x ;λ) =

{λe−λx x ≥ 0

0 otherwise

Remark:1. Usually we use X ∼ EXP(λ) to denote that the random variableX has an exponential distribution with parameter λ.2. In some sources, the pdf of exponential distribution is given by

f (x ; θ) =

{1θ e−

xθ x ≥ 0

0 otherwise

The difference is that λ→ 1θ .

f (x ;λ) =

{λe−λx x ≥ 0

0 otherwise

f (x ; θ) =

{1θ e−

xθ x ≥ 0

0 otherwise

f (x ;λ) =

{λe−λx x ≥ 0

0 otherwise

Remark:1. Usually we use X ∼ EXP(λ) to denote that the random variableX has an exponential distribution with parameter λ.

2. In some sources, the pdf of exponential distribution is given by

f (x ; θ) =

{1θ e−

xθ x ≥ 0

0 otherwise

f (x ;λ) =

{λe−λx x ≥ 0

0 otherwise

f (x ; θ) =

{1θ e−

xθ x ≥ 0

0 otherwise

Proposition

If X ∼ EXP(λ), then

E (X ) =1

λand V (X ) =

And the cdf for X is

F (x ;λ) =

{1− e−λx x ≥ 0

0 x < 0

Proposition

If X ∼ EXP(λ), then

E (X ) =1

λand V (X ) =

And the cdf for X is

F (x ;λ) =

{1− e−λx x ≥ 0

0 x < 0

Proof:

E (X ) =

∫ ∞0

xλe−λxdx

∫ ∞0

(λx)e−λxd(λx)

∫ ∞0

ye−y dy y = λx

λ[−ye−y |∞0 +

∫ ∞0

e−y dy ] integration by parts:u = y , v = −e−y

λ[0 + (−e−y |∞0 )]

Proof:

E (X ) =

∫ ∞0

xλe−λxdx

∫ ∞0

(λx)e−λxd(λx)

∫ ∞0

ye−y dy y = λx

λ[−ye−y |∞0 +

∫ ∞0

e−y dy ] integration by parts:u = y , v = −e−y

λ[0 + (−e−y |∞0 )]

Proof (continued):

E (X 2) =

∫ ∞0

x2λe−λxdx

∫ ∞0

(λx)2e−λxd(λx)

∫ ∞0

y 2e−y dy y = λx

λ2[−y 2e−y |∞0 +

∫ ∞0

2ye−y dy ] integration by parts

λ2[0 + 2(−ye−y |∞0 +

∫ ∞0

e−y dy)] integration by parts

λ22[0 + (−ye−y |∞0 )]

Proof (continued):

E (X 2) =

∫ ∞0

x2λe−λxdx

∫ ∞0

(λx)2e−λxd(λx)

∫ ∞0

y 2e−y dy y = λx

λ2[−y 2e−y |∞0 +

∫ ∞0

2ye−y dy ] integration by parts

λ2[0 + 2(−ye−y |∞0 +

∫ ∞0

e−y dy)] integration by parts

λ22[0 + (−ye−y |∞0 )]

Proof (continued):

V (X ) = E (X 2)− [E (X )]2 =2

λ2− (

λ)2 =

F (x) =

0λe−λy dy

0e−λy d(λy)

0e−zdz z = λy

= −e−z |x0= 1− e−x

Proof (continued):

V (X ) = E (X 2)− [E (X )]2 =2

λ2− (

λ)2 =

F (x) =

0λe−λy dy

0e−λy d(λy)

0e−zdz z = λy

= −e−z |x0= 1− e−x

Example (Problem 108)The article “Determination of the MTF of Positive PhotoresistsUsing the Monte Carlo method” (Photographic Sci. and

Engr., 1983: 254-260) proposes the exponential distributionwith parameter λ = 0.93 as a model for the distribution of aphoton’s free path length (µm) under certain circumstances.Suppose this is the correct model.

a. What is the expected path length, and what is the standarddeviation of path length?

b. What is the probability that path length exceeds 3.0?

c. What value is exceeded by only 10% of all path lengths?

Proposition

Suppose that the number of events occurring in any time intervalof length t has a Poisson distribution with parameter αt (where α,the rate of the event process, is the expected number of eventsoccurring in 1 unit of time) and that numbers of occurrences innonoverlappong intervals are independent of one another. Thenthe distribution of elapsed time between the occurrence of twosuccessive events is exponential with parameter λ = α.

e.g.the number of customers visiting Costco in each hour =⇒Poisson distribution;the time between every two successive customers visiting Costco=⇒ Exponential distribution.

Proposition

e.g.the number of customers visiting Costco in each hour =⇒Poisson distribution;

the time between every two successive customers visiting Costco=⇒ Exponential distribution.

Proposition

Example (Example 4.22)Suppose that calls are received at a 24-hour hotline according to aPoisson process with rate α = 0.5 call per day.Then the number of days X between successive calls has anexponential distribution with parameter value 0.5.The probability that more than 3 days elapse between calls is

P(X > 3) = 1− P(X ≤ 3) = 1− F (3; 0.5) = e−0.5·3 = 0.223.

The expected time between successive calls is 1/0.5 = 2 days.

Example (Example 4.22)Suppose that calls are received at a 24-hour hotline according to aPoisson process with rate α = 0.5 call per day.

Then the number of days X between successive calls has anexponential distribution with parameter value 0.5.The probability that more than 3 days elapse between calls is

P(X > 3) = 1− P(X ≤ 3) = 1− F (3; 0.5) = e−0.5·3 = 0.223.

Example (Example 4.22)Suppose that calls are received at a 24-hour hotline according to aPoisson process with rate α = 0.5 call per day.Then the number of days X between successive calls has anexponential distribution with parameter value 0.5.

The probability that more than 3 days elapse between calls is

P(X > 3) = 1− P(X ≤ 3) = 1− F (3; 0.5) = e−0.5·3 = 0.223.

“Memoryless” PropertyLet X = the time certain component lasts (in hours)and we assume the component lifetime is exponentially distributedwith parameter λ. Then what is the probability that thecomponent can last at least an additional t hours after working fort0 hours, i.e. what is P(X ≥ t + t0 | X ≥ t0)?

P(X ≥ t + t0 | X ≥ t0) =P({X ≥ t + t0} ∩ {X ≥ t0})

P(X ≥ t0)

=P(X ≥ t + t0)

P(X ≥ t0)

=1− F (t + t0;λ)

F (t0;λ)

= e−λt

P(X ≥ t + t0 | X ≥ t0) =P({X ≥ t + t0} ∩ {X ≥ t0})

P(X ≥ t0)

=P(X ≥ t + t0)

P(X ≥ t0)

=1− F (t + t0;λ)

F (t0;λ)

= e−λt

P(X ≥ t + t0 | X ≥ t0) =P({X ≥ t + t0} ∩ {X ≥ t0})

P(X ≥ t0)

=P(X ≥ t + t0)

P(X ≥ t0)

=1− F (t + t0;λ)

F (t0;λ)

= e−λt

“Memoryless” PropertyHowever, we have

P(X ≥ t) = 1− F (t;λ) = e−λt

Therefore, we have

P(X ≥ t) = P(X ≥ t + t0 | X ≥ t0)

for any positive t and t0.In words, the distribution of additional lifetime is exactly the sameas the original distribution of lifetime, so at each point in time thecomponent shows no effect of wear. In other words, thedistribution of remaining lifetime is independent of current age.

P(X ≥ t) = 1− F (t;λ) = e−λt

Therefore, we have

P(X ≥ t) = P(X ≥ t + t0 | X ≥ t0)

P(X ≥ t) = 1− F (t;λ) = e−λt

Therefore, we have

P(X ≥ t) = P(X ≥ t + t0 | X ≥ t0)

for any positive t and t0.

In words, the distribution of additional lifetime is exactly the sameas the original distribution of lifetime, so at each point in time thecomponent shows no effect of wear. In other words, thedistribution of remaining lifetime is independent of current age.

P(X ≥ t) = 1− F (t;λ) = e−λt

Therefore, we have

P(X ≥ t) = P(X ≥ t + t0 | X ≥ t0)

Gamma Distribution

DefinitionFor α > 0, the gamma function Γ(α) is defined by

Γ(α) =

∫ ∞0

xα−1e−xdx

Properties for gamma function:1. For any α > 1, Γ(α) = (α− 1) · Γ(α− 1) [via integration byparts];2. For any positive integer, n, Γ(n) = (n − 1)!;3. Γ( 1

2 ) =√π.

e.g. Γ(4) = (4− 1)! = 6 and Γ( 52 ) = 3

2 · Γ( 32 ) = 3

2 [ 12 · Γ( 1

2 )] = 34

Gamma Distribution

Γ(α) =

∫ ∞0

xα−1e−xdx

2 ) =√π.

e.g. Γ(4) = (4− 1)! = 6 and Γ( 52 ) = 3

2 · Γ( 32 ) = 3

2 [ 12 · Γ( 1

2 )] = 34

Gamma Distribution

Γ(α) =

∫ ∞0

xα−1e−xdx

Properties for gamma function:1. For any α > 1, Γ(α) = (α− 1) · Γ(α− 1) [via integration byparts];

2. For any positive integer, n, Γ(n) = (n − 1)!;3. Γ( 1

2 ) =√π.

e.g. Γ(4) = (4− 1)! = 6 and Γ( 52 ) = 3

2 · Γ( 32 ) = 3

2 [ 12 · Γ( 1

2 )] = 34

Gamma Distribution

Γ(α) =

∫ ∞0

xα−1e−xdx

Properties for gamma function:1. For any α > 1, Γ(α) = (α− 1) · Γ(α− 1) [via integration byparts];2. For any positive integer, n, Γ(n) = (n − 1)!;

3. Γ( 12 ) =

√π.

e.g. Γ(4) = (4− 1)! = 6 and Γ( 52 ) = 3

2 · Γ( 32 ) = 3

2 [ 12 · Γ( 1

2 )] = 34

Gamma Distribution

Γ(α) =

∫ ∞0

xα−1e−xdx

2 ) =√π.

e.g. Γ(4) = (4− 1)! = 6 and Γ( 52 ) = 3

2 · Γ( 32 ) = 3

2 [ 12 · Γ( 1

2 )] = 34

Gamma Distribution

Γ(α) =

∫ ∞0

xα−1e−xdx

2 ) =√π.

e.g. Γ(4) = (4− 1)! = 6 and Γ( 52 ) = 3

2 · Γ( 32 ) = 3

2 [ 12 · Γ( 1

2 )] = 34

Gamma Distribution

DefinitionA continuous random variable X is said to have a gammadistribution if the pdf of X is

f (x ;α, β) =

βαΓ(α) xα−1e−x/β x ≥ 0

0 otherwise

where the parameters α and β satisfy α > 0, β > 0. The standardgamma distribution has β = 1, so the pdf of a standard gammarv is

f (x ;α) =

Γ(α) xα−1e−x x ≥ 0

0 otherwise

Gamma Distribution

DefinitionA continuous random variable X is said to have a gammadistribution if the pdf of X is

f (x ;α, β) =

βαΓ(α) xα−1e−x/β x ≥ 0

0 otherwise

where the parameters α and β satisfy α > 0, β > 0. The standardgamma distribution has β = 1, so the pdf of a standard gammarv is

f (x ;α) =

Γ(α) xα−1e−x x ≥ 0

0 otherwise

Gamma Distribution

Remark:1. We use X ∼ GAM(α, β) to denote that the rv X has a gammadistribution with parameter α and β.2. If we let α = 1 and β = 1/λ, then we get the exponentialdistribution:

f (x ; 1,1

Γ(1)x1−1e−x/ 1

λ = λe−λx x ≥ 0

0 otherwise

3. When X is a standard gamma rv (β = 1), the cdf of X ,

F (x ;α) =

yα−1e−y

Γ(α)dy

is called the incomplete gamma function.There are extensive tables of F (x ;α) available (Appendix TableA.4).

Gamma Distribution

Remark:1. We use X ∼ GAM(α, β) to denote that the rv X has a gammadistribution with parameter α and β.

2. If we let α = 1 and β = 1/λ, then we get the exponentialdistribution:

f (x ; 1,1

Γ(1)x1−1e−x/ 1

0 otherwise

F (x ;α) =

yα−1e−y

Γ(α)dy

Gamma Distribution

f (x ; 1,1

Γ(1)x1−1e−x/ 1

0 otherwise

F (x ;α) =

yα−1e−y

Γ(α)dy

Gamma Distribution

f (x ; 1,1

Γ(1)x1−1e−x/ 1

0 otherwise

F (x ;α) =

yα−1e−y

Γ(α)dy

is called the incomplete gamma function.

There are extensive tables of F (x ;α) available (Appendix TableA.4).

Gamma Distribution

f (x ; 1,1

Γ(1)x1−1e−x/ 1

0 otherwise

F (x ;α) =

yα−1e−y

Γ(α)dy

Gamma Distribution

Proposition

If X ∼ GAM(α, β), then

E (X ) = αβ and V (X ) = αβ2

Furthermore, for any x > 0, the cdf of X is given by

P(X ≤ x) = F (x ;α, β) = F

)where F (•;α) is the incomplete gamma function.

Gamma Distribution

Proposition

If X ∼ GAM(α, β), then

E (X ) = αβ and V (X ) = αβ2

Furthermore, for any x > 0, the cdf of X is given by

P(X ≤ x) = F (x ;α, β) = F

)where F (•;α) is the incomplete gamma function.

Gamma Distribution

Example:The survival time (in days) of a white rat that was subjected to acertain level of X-ray radiation is a random variableX ∼ GAM(5, 4). Then what is

a. the probability that the survival time is at most 16 days;

b. the probability that the survival time is between 16 days and20 days (not inclusive);

c. the expected survival time.

Gamma Distribution

Chi-Squared Distribution

DefinitionLet ν be a positive integer. Then a random variable X is said tohave a chi-squared distribution with parameter ν if the pdf of Xis the gamma density with α = ν/2 and β = 2. The pdf of achi-squared rv is thus

f (x ; ν) =

2ν/2Γ(ν/2)x (ν/2)−1e−x/2 x ≥ 0

0 x < 0

The parameter ν is called the number of degrees of freedom(df) of X . The symbol χ2 is often used in place of “chi-squared”.

DefinitionLet ν be a positive integer. Then a random variable X is said tohave a chi-squared distribution with parameter ν if the pdf of Xis the gamma density with α = ν/2 and β = 2. The pdf of achi-squared rv is thus

f (x ; ν) =

2ν/2Γ(ν/2)x (ν/2)−1e−x/2 x ≥ 0

0 x < 0

The parameter ν is called the number of degrees of freedom(df) of X . The symbol χ2 is often used in place of “chi-squared”.

Remark:1. Usually, we use X ∼ χ2(ν) to denote that X is a chi-squared rvwith parameter ν;2. If X1,X2, . . . ,Xn is n independent standard normal rv’s, thenX 2

1 + X 22 + · · ·+ X 2

n has the same distribution as χ2(n).

Remark:1. Usually, we use X ∼ χ2(ν) to denote that X is a chi-squared rvwith parameter ν;

2. If X1,X2, . . . ,Xn is n independent standard normal rv’s, thenX 2

1 + X 22 + · · ·+ X 2

Remark:1. Usually, we use X ∼ χ2(ν) to denote that X is a chi-squared rvwith parameter ν;2. If X1,X2, . . . ,Xn is n independent standard normal rv’s, thenX 2

1 + X 22 + · · ·+ X 2

Weibull Distribution

DefinitionA random variable X is said to have a Weibull distribution withparameters α and β (α > 0, β > 0) if the pdf of X is

f (x ;α, β) =

{αβα xα−1e−(x/β)α x ≥ 0

0 x < 0

Remark:1. The family of Weibull distributions was introduced by theSwedish physicist Waloddi Weibull in 1939.2. We use X ∼WEB(α, β) to denote that the rv X has a Weibulldistribution with parameters α and β.

f (x ;α, β) =

0 x < 0

f (x ;α, β) =

0 x < 0

Remark:1. The family of Weibull distributions was introduced by theSwedish physicist Waloddi Weibull in 1939.

2. We use X ∼WEB(α, β) to denote that the rv X has a Weibulldistribution with parameters α and β.

f (x ;α, β) =

0 x < 0

Remark:3. When α = 1, the pdf becomes

f (x ;β) =

{1β e−x/β x ≥ 0

0 x < 0

which is the pdf for an exponential distribution with parameterλ = 1

β . Thus we see that the exponential distribution is a specialcase of both the gamma and Weibull distributions.4. There are gamma distributions that are not Weibull distributiosand vice versa, so one family is not a subset of the other.

Remark:

3. When α = 1, the pdf becomes

f (x ;β) =

{1β e−x/β x ≥ 0

0 x < 0

f (x ;β) =

{1β e−x/β x ≥ 0

0 x < 0

β . Thus we see that the exponential distribution is a specialcase of both the gamma and Weibull distributions.

4. There are gamma distributions that are not Weibull distributiosand vice versa, so one family is not a subset of the other.

f (x ;β) =

{1β e−x/β x ≥ 0

0 x < 0

Proposition

Let X be a random variable such that X ∼WEI(α, β). Then

E (X ) = βΓ

)and V (X ) = β2

The cdf of X is

F (x ;α, β) =

{1− e−(x/β)α x ≥ 0

0 x < 0

Proposition

Let X be a random variable such that X ∼WEI(α, β). Then

E (X ) = βΓ

)and V (X ) = β2

The cdf of X is

F (x ;α, β) =

{1− e−(x/β)α x ≥ 0

0 x < 0

Example:The shear strength (in pounds) of a spot weld is a Weibulldistributed random variable, X ∼WEB(400, 2/3).

a. Find P(X > 410).

b. Find P(X > 410 | X > 390).

c. Find E (X ) and V (X ).

d. Find the 95th percentile.

a. Find P(X > 410).

b. Find P(X > 410 | X > 390).

a. Find P(X > 410).

b. Find P(X > 410 | X > 390).

a. Find P(X > 410).

b. Find P(X > 410 | X > 390).

a. Find P(X > 410).

b. Find P(X > 410 | X > 390).

In practical situations, γ = min(X ) > 0 and X − γ has a Weibulldistribution.Example (Problem 74):Let X = the time (in 10−1 weeks) from shipment of a

defective product until the customer returns the

product. Suppose that the minimum return time is γ = 3.5 andthat the excess X − 3.5 over the minimum has a Weibulldistribution with parameters α = 2 and β = 1.5.

a. What is the cdf of X ?

b. What are the expected return time and variance of returntime?

c. Compute P(X > 5).

d. Compute P(5 ≤ X ≤ 8).

In practical situations, γ = min(X ) > 0 and X − γ has a Weibulldistribution.

Example (Problem 74):Let X = the time (in 10−1 weeks) from shipment of a

Lognormal Distribution

DefinitionA nonnegative rv X is said to have a lognormal distribution if therv Y = ln(X ) has a normal distribution. The resulting pdf of alognormal rv when ln(X ) is normally distributed with parameters µand σ is

f (x ;µ, σ) =

2πσxe−[ln(x)−µ]2/(2σ2) x ≤ 0

0 x < 0

Remark:1. We use X ∼ LOGN(µ, σ2) to denote that rv X have alognormal distribution with parameters µ and σ.2. Notice here that the parameter µ is not the mean and σ2 is notthe variance, i.e.

µ 6= E (X ) and σ2 6= V (X )

f (x ;µ, σ) =

2πσxe−[ln(x)−µ]2/(2σ2) x ≤ 0

0 x < 0

µ 6= E (X ) and σ2 6= V (X )

f (x ;µ, σ) =

2πσxe−[ln(x)−µ]2/(2σ2) x ≤ 0

0 x < 0

Remark:1. We use X ∼ LOGN(µ, σ2) to denote that rv X have alognormal distribution with parameters µ and σ.

2. Notice here that the parameter µ is not the mean and σ2 is notthe variance, i.e.

µ 6= E (X ) and σ2 6= V (X )

f (x ;µ, σ) =

2πσxe−[ln(x)−µ]2/(2σ2) x ≤ 0

0 x < 0

µ 6= E (X ) and σ2 6= V (X )

Proposition

If X ∼ LOGN(µ, σ2), then

E (X ) = eµ+σ2/2 and V (X ) = e2µ+σ2 · (eσ2 − 1)

The cdf of X is

F (x ;µ, σ) = P(X ≤ x) = P[ln(X ) ≤ ln(x)]

(Z ≤ ln(x)− µ

(ln(x)− µ

)x ≤ 0

where Φ(z) is the cdf of the standard normal rv Z .

Proposition

If X ∼ LOGN(µ, σ2), then

E (X ) = eµ+σ2/2 and V (X ) = e2µ+σ2 · (eσ2 − 1)

The cdf of X is

F (x ;µ, σ) = P(X ≤ x) = P[ln(X ) ≤ ln(x)]

(Z ≤ ln(x)− µ

(ln(x)− µ

)x ≤ 0

where Φ(z) is the cdf of the standard normal rv Z .

Example (Problem 115)Let Ii be the input current to a transistor and I0 be the outputcurrent. Then the current gain is proportional to ln(I0/Ii ).Suppose the constant of proportionality is 1 (which amounts tochoosing a particular unit of measurement), so that current gain =X = ln(I0/Ii ). Assume X is normally distributed with µ = 1 andσ = 0.05.

a. What is the probability that the output current is more thantwice the input current?

b. What are the expected value and variance of the ratio ofoutput to input current?

c. What value r is such that only 5% chance we will have theratio of output to input current exceed r?

Beta Distribution

DefinitionA random variable X is said to have a beta distribution withparameters α, β(both positive), A, and B if the pdf of X is

f (x ;α, β,A,B) =

1B−A ·

Γ(α+β)Γ(α)·Γ(β) ·

(x−AB−A

)α−1·(

B−xB−A

)β−1A ≤ x ≤ B

0 otherwise

The case A = 0,B = 1 gives the standard beta distribution.

Remark: We use X ∼ BETA(α, β,A,B) to denote that rv X has abeta distribution with parameters α, β, A, and B.

Beta Distribution

f (x ;α, β,A,B) =

1B−A ·

(x−AB−A

)α−1·(

B−xB−A

)β−1A ≤ x ≤ B

0 otherwise

Beta Distribution

f (x ;α, β,A,B) =

1B−A ·

(x−AB−A

)α−1·(

B−xB−A

)β−1A ≤ x ≤ B

0 otherwise

Beta Distribution

Proposition

If X ∼ BETA(α, β,A,B), then

E (X ) = A + (B − A) · α

α + βand V (X ) =

(B − A)2αβ

(α + β)2(α + β + 1)

Beta Distribution

Proposition

If X ∼ BETA(α, β,A,B), then

E (X ) = A + (B − A) · α

α + βand V (X ) =

(B − A)2αβ

(α + β)2(α + β + 1)

Beta Distribution

Example (Problem 127)An individual’s credit score is a number calculated based on thatperson’s credit history which helps a lender determine how muchhe/she should be loaned or what credit limit should be establishedfor a credit card. An article in the Los Angeles Times gave datawhich suggested that a beta distribution with parametersA = 150,B = 850, α = 8, β = 2 would provide a reasonableapproximation to the distribution of American credit scores.[Note: credit scores are integer-valued].

a. Let X represent a randomly selected American credit score.What are the mean value and standard deviation of thisrandom variable? What is the probability that X is within 1standard deviation of its mean value?

b. What is the approximate probability that a randomly selectedscore will exceed 750 (which lenders consider a very goodscore)?

Beta Distribution

Normal Distribution - Mathlzhang/teaching/3070spring2009/Daily Updates... · Normal Distribution...

Documents

Transcript of Normal Distribution - Mathlzhang/teaching/3070spring2009/Daily Updates... · Normal Distribution...

Standardized Score, probability & Normal Distribution Ibrahim Altubasi, PT, PhD The University of Jordan.

Basic Business Statistics, 11e © 2009 Prentice-Hall, Inc. Chap 6-1 The Normal Distribution.

ARIES ACT1 Core Physics Updates and Systems/1.5D comparisonsaries.ucsd.edu › ARIES › MEETINGS › 1205 › Kessel.pdf · 2012-05-31 · ARIES ACT1 Core Physics Updates and Systems/1.5D

The Normal Distribution - California State University ...ata20315/psy320/Lecture06_NormalDistribution.pdf · The Normal Distribution Cal State Northridge Ψ320 ... normal curve Can

Weibull Distribution - Home - Math - The University of Utahlzhang/teaching/3070summer2009/Daily Updates... · Weibull Distribution De nition A random variable X is said to have a

Module 13: Normal Distributionsbiostatcourse.fiu.edu/PDFSlides/Module13.pdf · 13 - 1 Module 13: Normal Distributions This module focuses on the normal distribution and how to use

STAT 730 Chapter 3: Normal Distribution Theory

Gaussian Distribution - cedar.buffalo.edu · 2 The Gaussian Distribution • For single real-valued variable x ... Normal Gamma • Both mean and precision unknown • Contour plot

Summarizing Measured Data - cse.wustl.edujain/iucee/ftp/k_12smd.pdf12-13 ©2010 Raj Jain Why Normal? There are two main reasons for the popularity of the normal distribution: 1. The

Standard Normal Distribution μ=0 and σ 2 =1. Confidence Intervals Scientists often use a sample standard deviation to construct a confidence interval.

Distribusi Normal Multivariat Dan Normal Bivariat

ψωριαση - updates

Status & Updates from CEPC Simulation – Detector optimizationias.ust.hk/program/shared_doc/2017/201701hep/HEP_20170124_Manqi_Ruan.p… · 14/01/2017 IAS@HKUST 1 Status & Updates

SPECIAL PROBABILITY DISTRIBUTION Budiyono 2011. BINOMIAL DISTRIBUTION (Bernoulli Distribution)

Distribución normal

PHYSICAL DATA ANALYSIS - Information … tables and formulas .....iii Uncertainty propagation iii Point estimates iv Normal distribution iv χ2 calculations v Pearson’s χ ...

Multivariate normal distribution - Khoury College of ...€¦ · The multivariate normal distribution is said to be "non-degenerate" when the symmetric covariance matrix is positive

The normal distribution is thelog-normaldistributionstat.ethz.ch/~stahel/talks/lognormal.pdf · 0 The normal distribution is thelog-normaldistribution Werner Stahel, Seminar für

Khoury College - Multivariate normal distribution...distributed if every linear combination of its k components has a univariate normal distribution. However, its importance derives

Inference about means But We don’t know swhitlock/bio300/overheads/...its distribution to a standard normal distribution: € Y This would give a probability distribution of the